Switched capacitors for ac-dc applications

ABSTRACT

An apparatus for conversion between AC and DC voltages includes a rectifier and first and second stages coupled to each other and having a regulator and a switched-capacitor circuit respectively. The first stage receives a first voltage from the rectifier and the second stage provides a second voltage. A controller controls the first and second stages.

RELATED APPLICATIONS

This application claims the benefit of the Feb. 16, 2016 filing date ofU.S. Provisional Application 62/295,660, the contents of which areherein incorporated by reference.

FIELD OF INVENTION

This invention relates to power conversion, and in particular, to powerconverters that use switched capacitors.

BACKGROUND

Many portable electrical devices must be charged from an AC source. Thisrequires a converter that, among other things, transforms the AC into DCsuitable for charging the device. The need to perform such conversionintroduces loss in the power-conversion circuit itself.

SUMMARY

The invention relates generally to adiabatic switched capacitor circuitsthat can be used with a high-voltage switch-mode regulator for use inadaptive charging.

In one aspect, the invention features an apparatus for convertingbetween AC voltage and DC voltage. Such an apparatus a rectifier coupledto a first stage that receives a first voltage from the rectifier andthat is coupled to a second stage that provides a second voltage. Thefirst stage includes a regulator and the second stage includes aswitched-capacitor converter. A controller controls the first and secondstages.

In some embodiments, the first stage includes a pre-regulating circuit,such as a fly back converter.

Further embodiments include those in which the second stage comprises atwo-stage switched-capacitor circuit having bypass switches forswitching first and second stages thereof into or out of theswitched-capacitor circuit during operation, thereby achieving differentvoltage conversion ratios, those in which the second stage comprises athree-stage switched-capacitor circuit having bypass switches forswitching first, second, and third stages thereof into or out of theswitched-capacitor circuit during operation, thereby achieving differentvoltage conversion ratios, and those in which the second stage comprisesa single-stage switched-capacitor circuit having switches thattransition between switch states so as to cause the switched-capacitorcircuit to operate at different voltage conversion ratios. Among theseare embodiments in which the the switches transition between at leastthree switch states.

In some embodiments, the controller comprises a primary side section anda secondary side section. In such embodiments, the primary side sectioncontrols a switch that selectively passes current through a primarywinding of a transformer and the secondary side controls the secondstage.

Other embodiments include a voltage divider for interfacing between thefirst and second stages. Among these are embodiments in which thevoltage divider is a constituent of the first stage and those in whichit is a constituent of the second stage.

In some embodiments, the controller includes an isolation barrierbetween a primary and secondary section thereof.

In other embodiments, the regulator includes an isolated regulator.Examples of such an isolated regulator include a magnetically-isolatedregulator, an electrically-isolated regulator, a galvanically-isolatedregulator, an optically-isolated regulator, and anelectromagnetically-isolated regulator.

Among the magnetically-isolated regulators that can be used is one thatincludes a fly-back converter. Examples of a fly-back converter includea quasi-resonant fly-back converter, an interleaved fly-back converter,a two-switch fly-back converter, and an active-clamp fly-back converter.

The magnetically-isolated regulator can also include a forwardconverter. Examples of a forward converter include a multi-resonantforward converter, an active-clamp forward converter, and a two-switchforward converter.

In some embodiments, the magnetically-isolated regulator includes ahalf-bridge converter. Examples of a half-bridge converter include anasymmetric half-bridge converter, a multi-resonant half-bridgeconverter, and an LLC resonant half-bridge converter.

In other embodiments, the magnetically-isolated regulator includes afull-bridge converter.

In some embodiments, the regulator is a non-isolated regulator. Examplesof suitable non-isolated regulators include a boost converter, abuck-boost converter, and a buck converter.

Also among the embodiments are those in which the regulator includes afirst functional component and a second functional component. In theseembodiments, the first and second functional components communicateenergy between them with no electrical conduction between them. Some ofthese embodiments include an intermediary that enables communication ofenergy between the first and second functional components. In somecases, the energy is stored in a magnetic field.

Also among the embodiments are those in which the switched-capacitorconverter includes an adiabatic circuit.

In other embodiments, the switched-capacitor converter is one that,during operation thereof, causes at least one capacitor therein toexperience a change in charged stored therein by causing charge to bepassed through a non-capacitive element.

Other embodiments include those in which the switched-capacitorconverter includes a multi-phase network and those in which it a cascademultiplier. Such a cascade multiplier can be diabatic or adiabatic.

Yet other embodiments include those in which the switched-capacitorconverter includes a ladder network, those in which it includes aDickson network, those in which it includes a series-parallel network,those in which it includes a Fibonacci network, and those in which itincludes a doubler network.

In some embodiments, the regulator includes a transformer. Among theseare embodiments in which a switch controls flow of current through oneside of the transformer. This switch would typically be under thecontrol of the controller. Also among these embodiments are those thathave a diode transitions between conducting and non-conducting states inresponse to operation of the switch.

In some embodiments, the converter is a constituent of another device,such as a travel adapter or a wall plug. Examples of such traveladapters or wall plugs are those that have a USB port. In suchembodiments, travel adapter receives an AC voltage and outputs a DCvoltage at the USB port.

In some embodiments, the second stage operates in discrete steps forproviding coarse adjustment of an input voltage and wherein the firststage provides fine adjustment of an input voltage.

Also among the embodiments are those in which the rectifier includes abridge rectifier. Among these embodiments are those in which the bridgerectifier includes bridge diodes and a bridge capacitor, with the bridgediodes being arranged to form the bridge. During the operation of suchembodiments, an output of the bridge is present across the bridgecapacitor.

Other embodiments include such features as active power-factorcircuitry, a fuse disposed to prevent excess current within the AC to DCconverter, and an electromagnetic interference filter disposed tosuppress radiation generated during operation of the AC to DC converter.

Embodiments also include those in which the controller alters a dutycycle or switching frequency in at least one switch in at least one ofthe stages, and those in which the controller is a feedback controllerthat adjusts switching frequencies of one or more switches in the firstand second stages based on a measurement of at least one of a voltageand current within the AC to DC converter.

In some embodiments, the second stage includes bypass switches that areconfigured to transition between different bypass-switch configurations,and a plurality of switched-capacitor stages. In such embodiments, eachbypass-switch configuration results in a different combination of theswitched-capacitor stages forming the switched-capacitor circuit. Amongthese embodiments are those that have a controller to cause transitionsof the bypass switches into different bypass-switch configurations.

In some embodiments, the wherein second stage includes a network ofswitched-capacitor networks. These can be interconnected to formdifferent switched-capacitor circuits. Among these are embodiments inwhich the switched switched-capacitor-network network includes a set ofbypass switches that interconnect a set of switched-capacitor networks.These bypass switches are configured to transition between bypass-switchstates, wherein each bypass-switch state corresponds to a differentinterconnection of switched-capacitor networks. Some of theseembodiments feature a controller configured to cause the bypass switchesto transition between different bypass-switch configurations.

Other embodiments of the invention include various combinations of theforegoing features.

In another aspect, the invention features a computer-accessible storagemedium that includes a database representative of one or more componentsof the apparatus described above. For example, the database may includedata representative of a switching network that has been optimized topromote low-loss operation of a charge pump.

Generally speaking, a computer accessible storage medium includes anynon-transitory storage media accessible by a computer during use toprovide instructions and/or data to the computer. For example, acomputer accessible storage medium may include storage media such asmagnetic or optical disks and semiconductor memories.

Software stored on such a medium falls into two sets: a first set thatconsists of software per se and a second set that is the complement ofthe first set. The claims are deemed to cover only the complement of thefirst set.

Generally, a database representative of the system may be a database orother data structure that can be read by a program and used, directly orindirectly, to fabricate the hardware comprising the system. Forexample, the database may be a behavioral-level description orregister-transfer level (RTL) description of the hardware functionalityin a high level design language (HDL) such as Verilog or VHDL. Thedescription may be read by a synthesis tool that may synthesize thedescription to produce a netlist comprising a list of gates from asynthesis library. The netlist comprises a set of gates that alsorepresent the functionality of the hardware comprising the system. Thenetlist may then be placed and routed to produce a data set describinggeometric shapes to be applied to masks. The masks may then be used invarious semiconductor fabrication steps to produce a semiconductorcircuit or circuits corresponding to the system. In other examples,Alternatively, the database may itself be the netlist (with or withoutthe synthesis library) or the data set.

In another aspect, the invention features a method that includeconverting an AC voltage into a DC voltage by providing the AC voltageto a rectifier that is coupled to a first stage that includes aregulator, the regulator being coupled to a second stage that includes aswitched-capacitor converter and controlling operation of the first andsecond stages to cause the second stage to output a DC voltage having adesired value.

These and other features of the invention will be apparent from thefollowing detailed description and the accompanying figures, in which:

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 shows a two-stage power-conversion circuit;

FIG. 2 shows the circuit of FIG. 1 with additional circuitry forreceiving an AC voltage;

FIG. 3 shows a first embodiment of a switched-capacitor architecture foruse in the power-conversion circuits of FIGS. 1 and 2;

FIG. 4 is a parts list for the embodiment shown in FIG. 3;

FIG. 5 shows a switching circuit contained in the stages of thepower-conversion circuit of FIGS. 1 and 2;

FIGS. 6 and 7 show operational efficiency of the power-conversioncircuit that uses the first embodiment as its second stage made on twodifferent dies with different sizes;

FIG. 8 shows the efficiencies associated with the circuits used in FIGS.6 and 7;

FIG. 9 shows a second embodiment of a switched-capacitor architecturefor use in the power-conversion circuits of FIGS. 1 and 2;

FIG. 10 is a parts list for the embodiment shown in FIG. 9;

FIGS. 11 and 12 show operational efficiency of the power-conversioncircuit of FIG. 9 that uses the second embodiment as its second stagemade on two different dies with different sizes;

FIG. 13 shows a third embodiment of a switched-capacitor architecturefor use in the power-conversion circuits of FIGS. 1 and 2;

FIGS. 14 and 15 show switching patterns for operation of the embodimentshown in FIG. 13; and

FIG. 16 shows the circuit of FIG. 2 incorporated into a travel adapter.

DETAILED DESCRIPTION

FIG. 1 shows a two-stage power-conversion circuit 11 having a firstterminal 12 that connects to the first stage and a second terminal 14that connects to a second stage. The first terminal 12 is at a firstvoltage V1 and the second terminal 14 is at a second voltage V2.

In the illustrated embodiment, the first stage is implemented as aswitch-mode pre-regulator 16 and the second stage is implemented as anadiabatic switched-capacitor circuit 18. However, in alternativeembodiments, this second stage is non-adiabatic, or diabatic.

The pre-regulator 16 can be implemented in a variety of ways, so long asthe essential function thereof, namely regulation of an output voltage,can be carried out. In the illustrated embodiment, the pre-regulator 16includes a pre-regulator switch S0, a transformer TO, a diode DO, and afilter capacitor CX. A particularly useful implementation of apre-regulator 16 is a magnetically-isolated converter, an example ofwhich is a fly-back converter.

A variety of fly-back converters can be used to implement thepre-regulator 16. These include a quasi-resonant fly-back converter, anactive-clamp fly-back converter, an interleaved fly-back converter, anda two-switch fly-back converter.

Other examples of magnetically-isolated converters are forwardconverters. Examples of suitable forward converters include amulti-resonant forward converter, an active-clamp forward converter, aninterleaved forward converter, and a two-switch forward converter.

Yet other examples of magnetically-isolated converters are half-bridgeconverters and full-bridge converters. Examples of half-bridgeconverters include an asymmetric half-bridge converter, a multi-resonanthalf-bridge converter, and an LLC resonant half-bridge converter.Examples of full-bridge converters include an asymmetric full-bridgeconverter, a multi-resonant full-bridge converter, and an LLC resonantfull-bridge converter.

It is also possible to implement the pre-regulator 16 using anon-isolated converter. Examples include a buck converter, a boostconverter, and a buck-boost converter.

As used herein, two functional components are said to be “isolated,” ormore specifically, “galvanically isolated,” if energy can becommunicated between those components without a direct electricalconduction path between those components. Such isolation thuspresupposes the use of another intermediary for communicating energybetween the two components without having actual electrical currentflowing between them. In some cases, this energy may includeinformation.

Examples include the use of a wave, such as an electromagnetic,mechanical, or acoustic wave. As used herein, electromagnetic wavesinclude waves that are in span the visible range, the ultraviolet range,and the infrared range. Such isolation can also be mediated through theuse of quasi-static electric or magnetic fields, capacitively,inductively, or mechanically.

Most functional components have circuitry in which different parts ofthe circuit are at different electrical potentials. However, there isalways a potential that represents the lowest potential in that circuit.This is often referred to as “ground” for that circuit.

When a first and second functional component are connected together,there is no guarantee that the electrical potential that defines groundfor the first component will be the same as the electrical potentialthat defines ground for the second circuit. If this is the case, and ifthese components are connected together, it will be quite possible forelectrical current to flow from the higher of the two grounds to thelower of the two grounds. This condition, which is called a “groundloop,” is undesirable. It is particularly undesirable if one of the twocomponents happens to be a human being. In such cases, the current inthe ground loop may cause injury.

Such ground loops can be discouraged by galvanically isolating the twocomponents. Such isolation essentially forecloses the occurrence ofground loops and reduces the likelihood that current will reach groundthrough some unintended path, such as a person's body.

The switched-capacitor circuit 18 can be implemented as aswitched-capacitor network. Examples of such networks include laddernetworks, Dickson networks, Series-Parallel networks, Fibonaccinetworks, and Doubler networks. These can all be adiabatically chargedand configured into multi-phase networks. A particularly usefulswitched-capacitor network is an adiabatically charged version of afull-wave cascade multiplier. However, diabatically charged versions canalso be used.

As used herein, changing the charge on a capacitor “adiabatically” meanscausing an amount of charge stored in that capacitor to change bypassing the charge through a non-capacitive element. A positiveadiabatic change in charge on the capacitor is considered adiabaticcharging while a negative adiabatic change in charge on the capacitor isconsidered adiabatic discharging. Examples of non-capacitive elementsinclude inductors, magnetic elements, resistors, and combinationsthereof.

In some cases, a capacitor can be charged adiabatically for part of thetime and diabatically for the rest of the time. Such capacitors areconsidered to be adiabatically charged. Similarly, in some cases, acapacitor can be discharged adiabatically for part of the time anddiabatically for the rest of the time. Such capacitors are considered tobe adiabatically discharged.

Diabatic charging includes all charging that is not adiabatic anddiabatic discharging includes all discharging that is not adiabatic.

As used herein, an “adiabatic switched-capacitor circuit” is a networkhaving at least one capacitor that is both adiabatically charged andadiabatically discharged. A “diabatic switched-capacitor circuit” is anetwork that is not an adiabatic switched-capacitor circuit.

Examples of pre-regulators 16, switched-capacitor circuits 18, theiraccompanying circuitry, and packaging techniques can be found U.S. Pat.Nos. 9,362,826, 9,497,854, 8,723,491, 8,503,203, 8,693,224, 9,502,968,8,619,445, 9,203,299, and 9,041,459, U.S. Patent Publications2016/0197552, 2015/0102798, 2014/0301057, 2013/0154600, 2015/0311786,2014/0327479, 2016/0028302, 2014/0266132, 2015/0077175, and2015/0077176, and PCT publications WO2014//062279, WO2015//138378,WO2015//138547, WO2016//149063, and WO 2017/007991, the contents ofwhich are herein incorporated by reference.

A controller 20 controls the operation of the first and second stages.The controller 20 includes a primary side 22 that controls the firststage and a secondary side 24 that controls the second stage. Anisolation barrier 26 separates the primary side 22 from the secondaryside 26.

The primary side 22 of the controller 20 controls the pre-regulatorswitch S0. Opening and closing the pre-regulator switch S0 controls thecurrent provided to a primary side of the transformer TO. This, in turn,controls the voltage across the filter capacitor CX. When thepre-regulator switch S0 is on, the diode DO is off and when thepre-regulator switch S0 is off, the diode DO is on.

The pre-regulator 16 also includes a regulator-output terminal 28maintained at an intermediate voltage VX1 that is lower than the firstvoltage V1. This regulator-output terminal 28 connects to the adiabaticswitched capacitor circuit 18. The adiabatic switched capacitor circuit18 thus receives this intermediate voltage VX1 and transforms it intothe second voltage V2.

The switched-capacitor circuit 18 operates in discrete steps. Thus, itonly provides coarse regulation of its output. It cannot provide fineregulation of its output. It is for the pre-regulator 16 to carry outthis fine regulation. The two-stage design shown in FIG. 1 reduces theneed for the pre-regulator 16 to sustain a high-current burden. Thismeans that the secondary winding of the transformer TO can instead carrya much smaller RMS current. This, in turn, lowers winding loss andreduces the voltage ripple at the regulator-output terminal 28. It alsomeans that the filter capacitor CX that couples the pre-regulator 16 tothe switched-capacitor circuit 18 can be made smaller.

However, the improved performance of the pre-regulator 16 cannot becompletely offset by the increased size and power loss of having theswitched-capacitor circuit 18 in the second stage. Therefore, it isimperative that the switched-capacitor circuit 18 be both extremelyefficient and small.

FIG. 2 shows a power-conversion circuit 10 similar to that shown in FIG.1 but with additional circuitry for receiving an AC voltage VAC providedby an AC source 4 and converting that AC voltage VAC into the secondvoltage V2. The AC voltage VAC is provided to input terminals of abridge rectifier 65 having bridge diodes DB1, DB2, DB3, and DB4 arrangedto form a bridge and having an output across a bridge capacitor CB. Theoutput across the bridge capacitor CB becomes the first voltage V1presented at the first terminal 12. A power-conversion circuit 10 ofthis type may be incorporated into a travel adapter 13, as shown in FIG.16. Such a travel adapter 13 outputs a DC voltage at a USB port 15.

Some embodiment include circuitry for controlling harmonic current andthus boosting the ratio of real power to apparent power that flowsthrough the power supply. This is particularly useful for power suppliesthat attach to a wall outlet that supplies an AC voltage. An example ofsuch circuitry is an active power-factor corrector 67 disposed betweenthe bridge rectifier 65 and the pre-regulator 16.

FIG. 2 also shows a fuse 61 between the AC power source 4 and theremaining components of the power-conversion circuit 10 for safety. Anelectromagnetic interference filter 63 is also provided to suppress theuncontrolled emission of electromagnetic waves that may arise duringoperation of the power-conversion circuit 10.

FIG. 3 shows a first embodiment of a switched-capacitor circuit 18 thatis designed to accept a nominal voltage of 20 volts and to produce avariety of output voltages, such as 5 volts and 10 volts. This isparticularly useful for Type-C travel adapters. This is because, unlikethe older USB standards, in which the output is always five volts, thenewer USB Type C standard permits higher output voltages, such as ten,fifteen, and even twenty volts.

The illustrated switched-capacitor circuit 18 features a firstswitched-capacitor stage 32, a second switched-capacitor stage 34, afirst bypass-switch S1, a second bypass-switch S2, and a thirdbypass-switch S3. An LC filter having an output inductor L1 and anoutput capacitor C0 permit adiabatic operation. By selectively openingand closing the bypass-switches S1, S2, S3, it is possible toselectively bypass selected ones of the first and secondswitched-capacitor stages 32, 34.

Each of the first and second stages 32, 34 is a 2× voltage dividerhaving a maximum voltage conversion from VX1 to VX2 of 4:1. Theresulting switched-capacitor circuit 18 is designed to accept anintermediate voltage VX1 of 20 volts and to provide an output voltage V2of either 20 volts, 10 volts, or 5 volts. Some embodiments deliver an 15volt output voltage, which is sometimes required by the Type-C standard.This can be provided by having the pre-regulator 16 deliver 15 volts tothe switched-capacitor circuit 18 instead of 20 volts and running theswitched-capacitor circuit 18 in the 1:1 mode.

The switched-capacitor circuit 18 shown in FIG. 3 has three modes ofoperation, a 1:1 mode, a 2:1 mode, and a 4:1 mode.

In the 1:1 mode, the first bypass-switch S1 closes, and the second andthird bypass-switches S2 and S3 open.

In the 2:1 mode, the second bypass-switch S2 closes and the first andthird bypass-switches S1 and S3 open.

In the 4:1 mode, the third bypass-switch S3 closes and the first andsecond bypass-switches S1 and S2 open. All bypassed stages run in alow-power mode to save power since they are not needed to providevoltage conversion (i.e., they are not switching at a specificfrequency).

FIG. 4 shows a component list for one implementation of theswitched-capacitor circuit 18 shown in FIG. 3. The components wereselected so the solution provides a high efficiency, a small solutionsize, and a maximum output voltage ripple of 100 mV peak-to-peak. Thetotal value column specifies the total amount of inductance and/orcapacitance required of the components at their operating condition. Forexample, capacitor C3 has a nominal dc bias of 5 volts, therefore, a 22μF capacitor was selected because it provides approximately 10 μF underthis condition.

FIG. 5 illustrates a circuit 36 inside the first stage. A similarcircuit is within the second stage. During operation, this circuittransitions between first and second states. In the first state, allswitches labeled “1” close and all switches labeled “2” open. In thesecond state, all switches labeled “1” open and all switches labeled “2”close. The circuit 36 alternates between the first and second state at aspecific frequency that is selected to produce a second intermediatevoltage VX2 that is half of the intermediate voltage VX1.

FIGS. 6 and 7 illustrate the predicted efficiency across output powerfor operation in the 2:1 mode and in the 4:1 mode at an intermediatevoltage VX1 of 20 volts for two different die sizes. FIG. 6 is foranominal die and FIG. 7 is for a larger die. Since the efficiency atfull-load is dominated by resistive losses, the larger silicon die sizewill result in improved performance. In some, but not all embodiments, anominal die is 12 mm² and a larger die is 16 mm²

It is worth noting that the power loss in the second stage isapproximately equal to the power loss in the first stage. This resultsin a larger percentage of the die being consumed by the second stage.Furthermore, the efficiency of the 5-volt output configuration is notequal to the square of the efficiency of the 10-volt outputconfiguration because some losses are common to both stages.

FIG. 8 summarizes performance at an intermediate voltage VX1 of 20 voltsand an output voltage T72 of 5 volts. The passive footprint area iscalculated by adding up the area of all of the passive components andadding 0.2 mm of space between them. The solution footprint area is thesum of the silicon die and the passive footprint area. As can be seenfrom the table, the full-load efficiency is higher with the larger diesize. The maximum height is 1.25 mm through the exclusive use of SMTcomponents.

Unlike, conventional switched-capacitor converters, the architecturedisclosed herein includes an LC filter that enables adiabatic chargingand discharging of the capacitors within each switched-capacitor stage.This adiabatic operation permits high efficiencies at small solutionsizes.

FIG. 9 illustrates another embodiment of the switched-capacitor circuit18 that is similar to that shown in FIG. 3. However, unlike in theswitched-capacitor circuit 18 shown in FIG. 3, the one shown in FIG. 9accepts an intermediate voltage VX1 of 40 volts instead of 20 volts.

To achieve this requirement, the switched-capacitor circuit 18 includesa third switched-capacitor stage 38. As before, an output voltage V2 ofeither 20 volts, 10 volts, or 5 volts. However, the operating modes arenow a 2:1 mode, a 4:1 mode, and an 8:1 mode. Remaining details on thestructure and operation of the embodiment shown in FIG. 8 are similar tothose for FIG. 3 and are omitted for brevity.

FIG. 10 shows a component list for one implementation of theswitched-capacitor circuit 18 shown in FIG. 8.

FIGS. 11 and 12 show predicted efficiency across output power for modes2:1, 4:1, and 8:1 at an intermediate voltage VX1 of 20 volts.

FIG. 13 shows an embodiment of a switched-capacitor circuit 18 thatavoids the use of multiple switched-capacitor stages and bypassswitches. Instead, it relies on a single switched-capacitor stage. Toachieve the various voltage conversion ratios, the embodiment shown inFIG. 13 uses different switching patterns for different voltageconversion ratios. Another difference between the embodiment shown inFIG. 13 and that shown in FIGS. 3 and 9 is that the embodiment shown inFIG. 13 cycles between four distinct states instead of two distinctstates. Like the first and second embodiments, this third embodimentalso has an LC filter at its output enabling adiabatic charging anddischarging of the capacitors C1-C3.

The third embodiment of the switched-capacitor circuit 18 can receive anintermediate voltage VX1 of 20 volts and produce a voltage of 20 volts,15 volts, 10 volts, or 5 volts. For example, if the intermediate voltageVX1 is 20 volts, FIGS. 14 and 15 illustrate the corresponding fourstates required to produce an output voltage VX2 of 5 volts and 15volts, respectively. For best performance, it is preferable that theswitched-capacitor circuit 18 switch between the states in the ordershown in FIGS. 14-15.

Having described the invention, and a preferred embodiment thereof, whatis claimed as new, and secured by letters patent is:

1-70. (canceled)
 71. An apparatus comprising: a switched-capacitorcircuit to operate in a plurality of switching patterns, theswitched-capacitor circuit comprising: a terminal to be coupled to apower-conversion circuit for converting an input voltage to a firstvoltage, wherein the input voltage is an AC voltage and the firstvoltage is a DC voltage, a first switch to be coupled to the terminal, asecond switch to be coupled to the first switch, a first capacitorterminal of a capacitor, and an inductor, a third switch to be coupledto the second switch, a second capacitor terminal of the capacitor, andthe inductor, and a fourth switch to be coupled to the third switch andthe second capacitor terminal of the capacitor; and a controller tocontrol the switched-capacitor circuit to operate in the plurality ofswitching patterns to cause the first voltage to be transformed to asecond voltage.
 72. The apparatus of claim 71, wherein the plurality ofswitching patterns includes a first switching pattern in which thesecond voltage is related to the first voltage by a first voltageconversion ratio.
 73. The apparatus of claim 72, wherein the pluralityof switching patterns includes a second switching pattern in which thesecond voltage is related to the first voltage by a second voltageconversion ratio different than the first voltage conversion ratio. 74.The apparatus of claim 71, wherein the controller being to control theswitched-capacitor circuit to operate in the plurality of switchingpatterns comprises the controller being to cycle the switched-capacitorcircuit between the plurality of switching patterns.
 75. The apparatusof claim 74, wherein cycling the switched-capacitor circuit between theplurality of switching patterns comprises cycling the switched-capacitorcircuit between the plurality of switching patterns at a frequencyselected to cause the second voltage to be related to the first voltageby a particular voltage conversion ratio.
 76. The apparatus of claim 71,wherein: the inductor and the fourth switch are to be coupled to anoutput capacitor; and an output voltage across the output capacitor isbased on the second voltage.
 77. The apparatus of claim 71, wherein theplurality of switching patterns comprises: a first switching pattern inwhich the first switch and the second switch are open and the thirdswitch and the fourth switch are closed; a second switching pattern inwhich the first switch and the third switch are open and the secondswitch and the fourth switch are closed; and a third switching patternin which the second switch and the fourth switch are closed and thefirst switch and the third switch are open.
 78. The apparatus of claim71, wherein the controller comprises: a primary section to control thepower-conversion circuit; and a secondary section to control theswitched-capacitor circuit, the secondary section to be separated fromthe primary section by an isolation barrier.
 79. The apparatus of claim71, wherein: the power-conversion circuit is to provide fine adjustmentof the input voltage; and the switched-capacitor circuit is to providecoarse adjustment of the input voltage.
 80. An apparatus comprising: apower-conversion circuit for converting an input voltage to a firstvoltage, wherein the input voltage is an AC voltage and the firstvoltage is a DC voltage; a switched-capacitor circuit to operate in aplurality of switching patterns, the switched-capacitor circuitcomprising: a terminal to be coupled to the power-conversion circuit toreceive the first voltage, a first switch to be coupled to the terminal,a second switch to be coupled to the first switch, a first capacitorterminal of a capacitor, and an inductor, a third switch to be coupledto the second switch, a second capacitor terminal of the capacitor, andthe inductor, and a fourth switch to be coupled to the third switch andthe second capacitor terminal of the capacitor; and a controller tocontrol the switched-capacitor circuit to operate in the plurality ofswitching patterns to cause the first voltage to be transformed to asecond voltage.
 81. The apparatus of claim 80, wherein the controllercomprises: a primary section to control the power-conversion circuit;and a secondary section to control the switched-capacitor circuit, thesecondary section to be separated from the primary section by anisolation barrier.
 82. The apparatus of claim 80, wherein the pluralityof switching patterns includes a first switching pattern in which thesecond voltage is related to the first voltage by a first voltageconversion ratio.
 83. The apparatus of claim 82, wherein the pluralityof switching patterns includes a second switching pattern in which thesecond voltage is related to the first voltage by a second voltageconversion ratio different than the first voltage conversion ratio. 84.The apparatus of claim 80, wherein the controller being to control theswitched-capacitor circuit to operate in the plurality of switchingpatterns comprises the controller being to cycle the switched-capacitorcircuit between the plurality of switching patterns.
 85. The apparatusof claim 84, wherein cycling the switched-capacitor circuit between theplurality of switching patterns comprises cycling the switched-capacitorcircuit between the plurality of switching patterns at a frequencyselected to cause the second voltage to be related to the first voltageby a particular voltage conversion ratio.
 86. The apparatus of claim 80,wherein: the inductor and the fourth switch are to be coupled to anoutput capacitor at a second terminal of the switched-capacitor circuit;and an output voltage at the second terminal is based on the secondvoltage.
 87. An apparatus comprising: a controller section to control aswitched-capacitor circuit to operate in a plurality of switchingpatterns to cause a first voltage to be transformed to a second voltage,wherein: the switched-capacitor circuit comprises: a terminal to becoupled to a power-conversion circuit for converting an input voltage tothe first voltage, wherein the input voltage is an AC voltage and thefirst voltage is a DC voltage, a first switch to be coupled to theterminal, a second switch to be coupled to the first switch, a firstcapacitor terminal of a capacitor, and an inductor, a third switch to becoupled to the second switch, a second capacitor terminal of thecapacitor, and the inductor, and a fourth switch to be coupled to thethird switch and the second capacitor terminal of the capacitor; and thecontroller section to control the switched-capacitor circuit isseparated by an isolation barrier from another controller section tocontrol the power-conversion circuit.
 88. The apparatus of claim 87,wherein the plurality of switching patterns comprises: a first switchingpattern in which the first switch and the second switch are open and thethird switch and the fourth switch are closed; a second switchingpattern in which the first switch and the third switch are open and thesecond switch and the fourth switch are closed; and a third switchingpattern in which the second switch and the fourth switch are closed andthe first switch and the third switch are open.
 89. The apparatus ofclaim 87, wherein: the power-conversion circuit is to provide fineadjustment of the input voltage; and the switched-capacitor circuit isto provide coarse adjustment of the input voltage.
 90. The apparatus ofclaim 87, wherein the controller being to control the switched-capacitorcircuit to operate in the plurality of switching patterns comprises thecontroller being to cycle the switched-capacitor circuit between theplurality of switching patterns.
 91. The apparatus of claim 90, whereincycling the switched-capacitor circuit between the plurality ofswitching patterns comprises cycling the switched-capacitor circuitbetween the plurality of switching patterns at a frequency selected tocause the second voltage to be related to the first voltage by aparticular voltage conversion ratio.
 92. The apparatus of claim 87,wherein: the inductor and the fourth switch are to be coupled to anoutput capacitor at a second terminal of the switched-capacitor circuit;and an output voltage at the second terminal is based on the secondvoltage.
 93. A method comprising: receiving, at a first terminal of aswitched-capacitor circuit, a first voltage from a power-conversioncircuit for converting an input voltage to the first voltage, whereinthe input voltage is an AC voltage and the first voltage is a DCvoltage, controlling the switched-capacitor circuit to cycle theswitched-capacitor circuit between a plurality of switching patterns tocause the first voltage to be transformed by the switched-capacitorcircuit to a second voltage, the switched capacitor circuit comprising:a first switch to be coupled to the first terminal, a second switch tobe coupled to the first switch, a first capacitor terminal of acapacitor, and an inductor, a third switch to be coupled to the secondswitch, a second capacitor terminal of the capacitor, and the inductor,and a fourth switch to be coupled to the third switch and the secondcapacitor terminal of the capacitor; and providing, at a second terminalof the switched-capacitor circuit, an output voltage based on the secondvoltage.
 94. The method of claim 93, wherein cycling theswitched-capacitor circuit between the plurality of switching patternscomprises cycling the switched-capacitor circuit between the pluralityof switching patterns at a frequency selected to cause the secondvoltage to be related to the first voltage by a particular voltageconversion ratio.
 95. The method of claim 93, wherein the plurality ofswitching patterns comprises: a first switching pattern in which thefirst switch and the second switch are open and the third switch and thefourth switch are closed; a second switching pattern in which the firstswitch and the third switch are open and the second switch and thefourth switch are closed; and a third switching pattern in which thesecond switch and the fourth switch are closed and the first switch andthe third switch are open.
 96. The method of claim 93, whereincontrolling the switched-capacitor circuit comprises controlling theswitched-capacitor circuit via a controller section for controlling theswitched-capacitor circuit that is separated by an isolation barrierfrom a controller section for controlling the power-conversion circuit.